KR101779952B1 - Method and apparatus for measuring and presenting eating rate - Google Patents

Abstract

The present invention relates to a medical device consisting of two or more devices (30, 32) adapted to measure a meal speed utilized to inform a person to eat according to a predetermined graphical meal curve (10, 24) And a method therefor. There is an in-memory means for automatically calculating an equation for a predetermined meal curve (10, 24) based on data obtained from the cumulative food intake in an adjusted meal through an initial curve followed by a training curve. The cumulative food intake is determined by the quadratic equation y = ax ² + bx + c, where y represents the food intake, a represents the slope change of the curve for time x, b represents the constant slope of the curve over time, And c represents the food intake at the start of the meal), and the initial curve has the same properties as the cumulative food intake obtained by controlling the meal.

Description

[0001] METHOD AND APPARATUS FOR MEASURING AND PRESENTING EATING RATE [0002]

The present invention relates to a medical device comprising two or more devices adapted to measure a meal speed utilized to inform a person to eat according to a predetermined graphical meal curve shown on the screen, and a method therefor.

"Mando-mail Termini ^® (Mandometer ^®)" a device named was developed in Sweden, Stockholm, Carolyn Scarborough Research Institute, Mando-mail Termini ^® application nerve endocrinology department of the clinic. It consists of a balance connected to the computer. The plate is placed on the scale, the patient places a measured portion of the food determined by the therapist on the plate, and the computer records and stores the weight loss from the plate while the patient is eating.

This yields a meal-speed curve that the patient can see on a computer screen during a meal and can be compared to a predetermined meal curve on the screen. At regular intervals, the grading scale appears on the computer monitor and the patient evaluates her / his fullness / satiety. The scale has a numeric value of 0 (no satiety) to 100 (fullness). By evaluating their satiety, the patient appears on the screen and produces a developmental curve of fullness (fullness). Patients can therefore compare their development of fullness to the predetermined " normal "fullness curve again on the screen. "Mando-mail Termini ^® - training" for the patient should gradually adapt to more normal patterns of eating and satiety according to the training curve shown in the monitor during the meal. These methods were originally developed for the treatment of dietary disorders such as anorexia and bulimia nervosa: it is estimated to have an estimated mitigation rate of 75% in randomized controlled trials. A few years ago, most of the obese are eating at a high constant speed, and the machete was suggested that this observation is confirmed in a pilot study on obese adolescents using the mail Termini ^®.

Mando-mail device Termini ^® was registered to fenugreek patent US5817006 bug (Bergh) in the United States, for example in some countries.

The present invention provides a medical device that measures the meal rate used to inform a person to eat at a normal meal rate to help people feel full after a meal and provides a medical device to squeeze or drain meat in a controlled, For one purpose. Recent scientific studies have shown that the rate of slowing meals prevents people from overeating by eating in a desirable way with obesity's clinical consequences of reducing weight.

Thus, the present invention describes a medical device consisting of two or more devices adapted to measure a meal rate utilized to inform people to eat according to a predetermined graphical meal curve shown on the screen. Thereby, the present invention includes:

A device having a screen for storing a predetermined graphical meal curve in memory, the first device having at least one of a remote near field radiation and a wired communication function for communicating with a second device associated therewith;

An associated second device configured to communicate with the first device and having at least one of remote proximity radiation and wired communication capabilities adapted to the first device;

Measuring the food weight on the balance in a measurement period of time length and transmitting the food weight to the first device via a communication function when the food is removed from the balance by eating the food, By means of the software on the first device in which the amount of food removed during a period is stored, the weight of the food removed when the food is removed from the balance is displayed on the screen as a measurement point, Form a graphical meal curve; And additionally:

Wherein the cumulative food intake is a quadratic equation y = ax ² + bx + c where y represents the food intake, a represents the slope change of the curve over time, b represents the constant slope of the curve over time, The initial curve represents the initial rate, and c represents the food intake at the beginning of the meal), and the initial curve is the cumulative food intake from the control meal, adjusted by the training curve following the initial curve, Means for automatically calculating an equation for a predetermined meal curve based on data obtained from the intake.

In a preferred embodiment of the invention, the equation for each training curve is a slowing meal style characterized by a < -1, or on the basis of a linear form of the equation characterized in that a in the equation is a > , The normal initial meal rate is assumed to be 48 grams / minute, the normal food intake is 320-360 grams and the normal meal period is 12-15 minutes, so the pseudo code for the meal rate is next It is done:

y = ax ² + bx + c

Food intake = 600 if y> 720, y-70

Initial meal rate = b- (¼ (b-48))

Deceleration or linear speed =

Another embodiment includes integrating the balance and the first device into one device.

An additional embodiment includes having the balance having a balance measuring surface formed from a bowl or plate for placing food.

Still an additional embodiment provides that the balance is pocket portable.

An embodiment also provides a depiction of non-linear eating behavior, in which a predetermined graphical curve has been found to mimic the human eating preference behavior through scientific research.

Another embodiment includes the predetermined graphical curve describing the linear velocity of the eating behavior.

Still another additional embodiment provides that a predefined saturation graphical curve is displayed on the screen to compare with a saturation rating that occurs during a predetermined time interval on the screen by a person utilizing the device.

Additionally, the present invention describes a method employed in a medical device consisting of two or more devices adapted to measure meal speed utilized to inform people to eat along a predetermined graphical meal curve shown on the screen. The process according to the invention thus comprises:

Storing a predetermined graphical meal curve in a memory of a device having a screen, the first device having at least one of remote proximity radiation and wired communication capabilities for communication with a second device associated therewith;

Configuring the balance to communicate with the first device through a second associated device having at least one of a remote proximity radiation and wired communication capability adapted to the first device;

Measuring the food weight on the balance in a measurement period of time length, transmitting the food weight to the first device via a communication function when the food is removed from the balance by the person eating the food, Shows the weight of food removed by the measuring point on the screen when the food is removed from the scale, via the software means in the first device where the amount of food is stored, to form a graphical meal curve in real time compared to a predetermined meal curve step; And additionally:

Wherein the cumulative food intake is a quadratic equation y = ax ² + bx + c where y represents the food intake, a represents the slope change of the curve over time, b represents the constant slope of the curve over time, , And c represents the food intake at the beginning of the meal), and the initial curve is the cumulative food intake of the control meal, the control curve following the initial curve, the cumulative food of the control meal Automatically calculating an equation through in-memory means for a predetermined meal curve based on data obtained from the ingestion.

The method of the invention is also subject to the appended dependent claims of the above-mentioned apparatus.

Hereinafter, for a better understanding of the present invention, reference is made to the accompanying drawings in the accompanying description of the text, together with its embodiments and given examples, wherein:
Figure 1 shows a graphic for a linear eating behavior;
Figure 2 shows a graphic for a slowing meal action; And
Figure 3 schematically illustrates an embodiment of a device having the radio function of a radiotelephone connected to the balance via near-field radiation communication in accordance with the present invention.

The invention for example relates to a mobile phone, PDA, computer, PC, laptop, iPhone ^® (Iphone ^®), Android, and such devices are medical measurement device is configured as the first device. The second device is in the form of a scale for measuring all parts of the food that a person eats from a plate or bowl placed on the scale during a meal or the like. This device is used to inform people who suffer from anorexia, obsessive-compulsive disorder, obesity, other gastrointestinal disorders, and those who want to control their food intake and maintain it appropriately.

A study on obesity among children and adolescents in Sweden, Stockholm, Carolyn Scarborough Research Institute, Mando-mail Termini ^® developed by Applied neural endocrinology department of the clinic, "Mando-mail Termini ^®" is England's Bristol Royal to take advantage of the (prior art) It was done at the Bristol Royal Hospital for Children. It consists of a balance connected to the computer. Place the plate on the balance; The patient places the measured portion of the food on the plate, which is determined by the therapist, and the computer records and stores the weight loss from the plate while the patient is eating.

This yields a meal-rate curve that the patient can see on a computer screen during their meal and compare with a predetermined meal curve on the screen. At regular intervals, the grade scale appears on the computer monitor and the patient evaluates her / her satiety level. The scale has a numeric value of, for example, 0 (unsatisfied) to 100 (fullness). As the patient evaluates their fullness, the point appears on the screen and produces a developmental curve of fullness (fullness). Patients can thus compare their development of fullness to the predetermined " normal "fullness curve again on the screen. "Mando-mail Termini ^® - training" for the patient shown in the monitor during the meal, and gradually adapt to more normal patterns of eating and satiety according to the training curve. These methods were originally developed for the treatment of dietary disorders such as anorexia and bulimia nervosa.

In that the pattern would be able to prevent individuals overeat, the study announced that further enhanced results, ie machete-mail Termini ^® Curve shape deceleration can have a diet for training. As used herein, the average velocity analysis of a meal ignores minute-to-minute changes during a meal, and this can account for the absence of statistically significant effects in the simplified meal rate measurement.

The discovery of a slow meal was approved by Elsevier on March 18, 2008 and received on October 2, 2008 in a second format, approved and published October 9, 2008. (A), Cecilia Bergh (a), Ulf Brodin (a), (b), and (c) in the following scientific articles: "Decelerated and linear eaters: Per Soedersten (a)] has been subjected to additional scientific testing and analysis:

a) Sweden, S-141 57 Huddinge, Noubaum, AB Mando, Mando Meter and Mandorean Clinic, and Carolinska Institute, Applied Neuro Endocrinology Department, NVS

b) Sweden, S-171 77 Stockholm, Carolinska Institute, LIME, Department of Medical Statistics.

Another published paper is Elsevier, Physics and Behavior, Linear eaters turned decelerated on July 4, 2008, revised on November 14, 2008, and approved November 25, Reduction of a risk for disordered eating ?, Modjtaba Zandian, Ioannis Ioakimidis, Cecilia Bergh, Per Soedersten].

Hereinafter, one embodiment of a device that is a scientific discovery utilized for a slowing meal rate is described as an example of many possible devices. It will be appreciated that the equation utilized in the present invention may also be suitable for the non-decelerated linear meal / linear meal behavior, e.g., as described in FIG.

In Figure 1, graphics are methoxy Terre ^® alone measuring device or shown for the linear meal of the prior standard (standard) for determining the eating rate and filling to take advantage of the device of the present invention. In this way, it is depicted with a predetermined linear speed meal curve 10 alone methoxy Terre real time curve of a meal in fact to be recorded from the person utilizing ^® measurement instrument 12. The curve 12 should correspond to as much of the linear curve 10 as possible to achieve an acceptable normal eating speed and this can help a person to eat or squeeze according to the physical conditions of a person.

Point 14 shows how a diner grades fullness over a predetermined time period / interval, which, if connected by a line, constitutes the curve itself, which shows the fullness / fullness of the diner. In addition, Figure 1 shows a predefined S-shaped curve 16 mimicking a normal wheat grade compared to a wheat grade 14 made by a person who eats. Button 18 is a push button that is utilized to browse among different meals stored in a wireless capable device in accordance with an embodiment of the present invention. Also shown in FIG. 1 is an information button 20, which, for example, shows the amount of food eaten during a period and a duration of a period. Also shown is an icon for the battery charge 22 of the wireless device.

Figure 2 shows a curve and function similar to that of Figure 1, with curve 24 showing a difference in slowing meal rates according to recent scientific studies, which appears to better illustrate the average person's eating speed.

Figure 3 schematically illustrates an embodiment of many possible devices according to the present invention, including a cellular phone 30 having a display screen of any known structure, such as having a conventional keypad or touch screen. In addition, the instrument preferably includes a small pocket sized scales 32. It also shows a plate or bowl (34) that is used to place food on it when a person is eating. The wireless device 30 and the balance 32 communicate with each other via what is shown schematically as a two-way arrow, such as near infrared radiation, e.g., Bluetooth or infrared (IR).

The communication between the balance and the wireless device 30 transmits how much food is removed from the plate 34 by the person in the meal interval and the data of the meal speed. The person also grades the fullness 14 on the wireless device screen at predetermined time intervals. Thus, the curve for meal speed 12 and fullness 14, according to FIGS. 1 and 2, indicates that the person eats from the plate 34 has its meal speed on curves 10 and 24 for a predetermined meal speed Is displayed so as to be able to compare the fullness of its curve 16 with the fit and / or fullness.

In addition, the software means is utilized to transmit the stored time period to the remote server 40 connected to the computer terminal 42 via the first device 30 cellular phone function for registration of the curve for the meal rate 12. The means of the server 40 may be adapted to provide the first device 30 with information about which predefined graphical meal curves 10 and 24 are to be utilized from any geographical location resulting from previous registration of the real- You can send an adjustment command to apply the registered meal behavior of the person using the device.

The server 40 with the mobile phone 30 and the terminal 42 is connected to the base station (BST) 44 via the base station (BST) 44 and the mobile service switch 48 via the control station Communication. The communication between the device 40, 42, 44, 46, 48 and the cell phone 30 with the balance 32 is shown in FIG. 3 through a double arrow.

The person utilizing the device of the present invention may be the worst case scenario with an immediate need for medical management and thus the location of the person utilizing the device in one embodiment may be, for example, Location system (GPS). Another possibility of tracking a person can be accomplished by utilizing the signaling system of telephone 30 that includes wireless mobile location data in the telephone signal. The wireless mobile location data accurately locate the real time geographic location of the phone 30, and in most cases also the location of the user of the phone 30. [

Thus, FIG. 3 shows an embodiment of a medical device of the present invention comprised of two or more devices adapted for mealtime 12 measurement to be utilized to inform people to eat according to predetermined graphical meal curves 10, (30,32). &Lt; / RTI &gt; As such, it includes a device 30 with a screen for storing predetermined graphical meal curves 10, 24 in memory. The first device 30 has at least one of a remote near-field radiation and wired communication capability for communication with the associated second device 32. Wired connections, such as USB, VGA, or other known connection methods, may be utilized when the first device is a laptop or other known computer, for example.

The associated second device 32 scales are configured to communicate with the first device 30 and have at least one of the remote proximity radiation and wired communication capabilities adapted to the first device 30. The food weight on the scale 32 is measured in the measurement period of time length and the food weight is transmitted to the first device 30 through the communication function when the food is removed from the balance by the person who eats the food. This shows the weight of the food removed to the measuring point on the screen as the food is removed from the scale, via the software means in the first device (30) where the amount of food removed during a period of time is stored in the memory, Time graphical meal curve 12 compared to the curves 10,

In addition, the present invention provides in-memory means for automatically calculating an equation for a predetermined meal curve (10, 24) based on data obtained from cumulative food intake in an adjusted meal via a training curve following the initial curve, for example software Means. Cumulative food intake is a quadratic equation y = ax ² + bx + c where the variable y represents the food intake, a represents the slope change of the curve with respect to the time represented by the variable x, , And c represents the food intake at the start of a meal), where the initial curve has the same properties as the cumulative food intake obtained from the conditioned meal.

In one preferred embodiment of the present invention, the equation for each training curve is based on the linear form of the equation characterized by a slowing-down style characterized by a < -1, or where a in the equation is a? , The normal initial meal rate is considered to be 48 grams / minute, the normal food intake is 320-360 grams, and the normal meal period is 12-15 minutes, thus the pseudo code for the meal rate is as follows:

y = ax ² + bx + c

Food intake = 600 if y> 720, y-70

Initial meal rate = b- (¼ (b-48))

Deceleration or linear speed according to the value of a =

Another embodiment includes integrating the balance and the first device into one device. An additional embodiment includes having the balance having a balance measuring surface formed from a bowl or plate for placing food.

Still an additional embodiment provides that the balance is pocket portable. One embodiment provides a depiction of nonlinear eating behavior that has been found to pre-determined graphical curves mimicking human diet behavior through scientific research.

Another embodiment includes the predetermined graphical curve describing the linear velocity of the eating behavior. Still another additional embodiment provides what is shown on the screen so that a predetermined graphical curve of satiety is compared to a satiety level created during a predetermined time interval on the screen by a person utilizing the device.

In addition, the invention includes a method adapted to a medical device consisting of two or more devices adapted for mealtime rate measurement utilized to inform people to eat according to a predetermined graphical meal curve shown on the screen. The method of the present invention thus includes storing a predetermined graphical meal curve in a memory of a device with a screen. The first device has at least one of a remote proximity radiation and wired communication capability for communicating with the associated second device. The balance is configured to communicate with the first device through a second device associated therewith, which has at least one of a remote proximity radiation and wired communication capability adapted to the first device. When the food is removed from the balance by the person eating the food, the food is weighed by the balance in the measurement period of time length, and the food weight is transmitted to the first device through the communication function. This shows the weight of the food removed to the measuring point of the screen when the food is removed from the balance, via software means in the first device where the amount of food removed during one period is stored in memory, compared with a predetermined meal curve Thereby forming a real-time graphical meal curve.

In addition, the method of the present invention comprises the step of automatically calculating an equation through in-memory means for a predetermined meal curve based on data obtained from the cumulative food intake in the conditioned meal through the training curve following the initial curve. The cumulative food intake is determined by the quadratic equation y = ax ² + bx + c, where y represents the food intake, a represents the slope change of the curve for time x, b represents the constant slope of the curve over time, And c represents the food intake at the start of the meal), and the initial curve has the same properties as the cumulative food intake obtained by controlling the meal.

The present invention is not limited to the given embodiments and examples shown above. One of ordinary skill in the art can derive additional possible embodiments by a set of appended claims.

Claims (16)

Having a screen for storing predetermined graphical meal curves (10, 24) in the memory and having a screen for storing the first graphical meal curve (10, 24) in memory, the first device having at least one of remote near field radiation and wired communication capabilities for communication with the associated second device Device (30);
The associated second device (32) configured to communicate with the first device (30), an associated second device having at least one of a remote proximity radiation and wired communication capability adapted to the first device (30) 32) Balance;
Measuring the weight of the food on the scale (32) in a measurement period of time length, and measuring the weight of the first device (30) via the communication function when food is removed from the scale by a person eating the food, To a measuring point on the screen when food is removed from the balance, via software means in the first device (30) in which the quantity of food removed for a period of time is stored in the memory Displaying the weight of the removed food to form a graphical meal curve (12) in real time compared to the predetermined graphical meal curves (10, 24); And additionally:
The cumulative food intake is determined by the quadratic equation y = ax ² + bx + c, where y represents the food intake, a represents the slope change of the curve over time, b represents the constant slope of the curve over time, And c represents the food intake at the start of the meal), and the initial curve satisfies the cumulative food intake obtained by controlling the meal, In memory means for automatically calculating an equation for a predetermined graphical meal curve (10, 24) based on data obtained from the intake,
(12) adapted for real time graphical meal curves (12) measurements utilized to inform people to eat according to predetermined graphical meal curves (10, 24) appearing on the screen. 30, and 32,
Based on the linear form of the equation, wherein the equation for each training curve is a slowing meal style characterized by a < -1, or a where a > a > -1 in the equation, 48 grams / minute, the normal food intake is 320-360 grams and the normal meal period is 12-15 minutes, so the pseudo code for the meal rate is:
y = ax ² + bx + c
(600 if food intake = y> 720, y-70 otherwise
Initial meal rate = b- (¼ (b-48))
Deceleration or linear speed =

)
And a medical device. delete The medical device according to claim 1, wherein the balance (32) and the first device (30) are integrated into one device. The medical device according to claim 1, wherein the balance (32) has a balance measuring surface formed from a bowl or plate for placing food. The medical device according to claim 1, wherein the balance (32) is portable in a pocket. The medical device of claim 1, wherein the predetermined graphical meal curve (24) describes a nonlinear meal behavior that has been found to simulate human preferred eating behavior through scientific research. The medical device according to claim 1, wherein the predetermined graphical meal curve (10) depicts a linear speed meal behavior. A method according to claim 1, characterized in that a pre-measured graphical curve (16) of fullness is shown on the screen and a satiety class (14) created during a predetermined time interval on the screen by a person utilizing the device ). &Lt; / RTI &gt; (10, 24) in a memory of a device (30) with a screen, the first device (30) having at least one of a remote proximity radiation and a wire communication function for communicating with a second device );
Configuring a balance communicating with the first device (30) via the associated second device (32) having at least one of a remote proximity radiation and wired communication capability adapted to the first device (30);
Measuring the weight of the food on the balance (32) in a measurement period of time length and transmitting the food weight to the first device (30) via the communication function when the food is removed from the balance by the person eating the food And the weight of food removed to the measurement point on the screen when the food is removed from the scale, via software means in the first device (30) in which the amount of food removed during a period of time is stored in the memory To form a graphical meal curve (12) in real time compared to said predetermined graphical meal curves (10, 24); And additionally:
The cumulative food intake is determined by the quadratic equation y = ax ² + bx + c, where y represents the food intake, a represents the slope change of the curve over time, b represents the constant slope of the curve over time, And c represents the food intake at the start of the meal), and the initial curve satisfies the cumulative food intake obtained by controlling the meal, Automatically calculating an equation through the in-memory means for a predetermined graphical meal curve (10, 24) based on data obtained from the ingestion
(12) adapted to measure a real time graphical meal curve (12) utilized to inform people to eat according to predetermined graphical meal curves (10, 24) appearing on the screen Is adapted to the configured medical device (30, 32)
Based on the linear form of the equation, wherein the equation for each training curve is a slowing meal style characterized by a < -1, or a where a > a > -1 in the equation, 48 grams / minute, the normal food intake is 320-360 grams and the normal meal period is 12-15 minutes, so the pseudo-code for the meal rate is:
y = ax ² + bx + c
(600 if food intake = y> 720, y-70 otherwise
Initial meal rate = b- (¼ (b-48))
Deceleration or linear speed =

)
&Lt; / RTI &gt; delete 10. The method of claim 9, wherein the balance (32) and the first device (30) are integrated into a single device. 10. The method according to claim 9, wherein the balance (32) has a balance measuring surface formed of a bowl or plate for placing food. 10. The method of claim 9, wherein the scales (32) are pocketable. 10. The method of claim 9, wherein the predetermined graphical meal curve (24) describes a non-linear meal behavior that has been found to mimic human preferred eating behavior through scientific research. 10. The method of claim 9, wherein said predetermined graphical meal curve (10) depicts a linear speed meal behavior. 10. A method according to claim 9, characterized in that a pre-measured graphic curve (16) of fullness is shown on the screen and a satiety class (14) created during a predetermined time interval on the screen by a person utilizing the device ). &Lt; / RTI &gt;

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